Wavelength locked fiber-coupled diode-laser bar

ABSTRACT

In apparatus for wavelength stabilizing and spectrally narrowing an output beam of a diode-laser, a cylindrical lens is arranged to collimate the beam in the fast axis of the diode laser without reducing divergence in the slow axis of the diode-laser. A length of optical fiber is arranged to receive the fast-axis collimated beam from the lens. The optical fiber has a core surrounded by a first cladding, the first cladding being surrounded by a second cladding. The core of the optical fiber has an elongated cross section and includes a wavelength selective Bragg grating. The core functions as a low-mode core in the width direction of the cross section. The length direction of the core is aligned with the fast axis of the diode-laser. The fast-axis collimated beam and the low mode width of the core provides that the Bragg grating only reflects light that propagates parallel the longitudinal axis of the fiber. Light reflected from the grating is fed back to the diode-laser for stabilizing the wavelength and spectrally narrowing the diode-laser output beam.

TECHNICAL FIELD OF THE INVENTION

The present invention relates generally to stabilizing the output of a linear diode-laser array or diode-laser bar. The invention relates in particular to stabilizing the output of a diode-laser bar when that output is coupled into an optical fiber array.

DISCUSSION OF BACKGROUND ART

Diode-laser light is commonly used for optically pumping solid-state lasers and fiber lasers. As light from a single diode-laser is often insufficiently powerful for such pumping, it is usual to use light from a plurality of diode-lasers arranged in a linear array. Such an array is commonly referred to by practitioners of the art as a diode-laser bar. The light from the diode-lasers in the bar must be collected by an optical arrangement that makes the sum of the outputs of the diode-lasers available for pumping.

Light is emitted from a diode-laser as a diverging beam. The beam diverges strongly, for example at about 35 degrees, in one axis, termed the fast axis, and diverges weakly, for example at about 10 degrees, in an axis (the slow axis) perpendicular to the fast axis. In a diode-laser bar individual diode-lasers (emitters) are arranged, spaced apart, linearly, in the slow axis direction. In a high power diode-laser of the type used for optical pump light is emitted in a plurality of modes (multimode output). A preferred method of collecting the outputs of the plurality of emitters of a diode-laser bar is to couple the individual emitter outputs into a corresponding plurality of multimode optical fibers having entrance ends thereof arranged in a linear array aligned with the slow axis of the diode laser bar. A cylindrical microlens is used to collimate the emitter output in the fast axis the output is coupled into the fibers. Output ends of the optical fibers are formed into a bundle. Light output from the bundle can be collected by a lens and focused directly into a solid-state gain medium or into a single optical fiber, which can be a transport fiber or a fiber laser to be pumped.

In the gain medium of a solid-state laser or a fiber laser absorption of optical pump light can often only occur in a narrow band of wavelengths, for example, about 1 nanometer (nm) wide. This narrow band of wavelengths is centered on a fixed, peak absorption wavelength that is characteristic of the gain medium. Absent any constraint, diode-laser light is emitted in a relatively broad spectrum of wavelengths, for example between 2 nm and 5 nm. Accordingly, for optimizing optical pumping efficiency, it is preferable to provide a constraint that narrows the emission bandwidth and stabilizes the center wavelength of this narrowed emission bandwidth at the characteristic peak absorption wavelength of the gain medium.

One arrangement that has been used to narrow the bandwidth and stabilize the wavelength of the output of a single mode diode-laser coupled into the core of a single mode fiber, is to write a fiber Bragg grating into the core of the fiber. The refractive index modulation and the period of modulation of the Bragg grating are selected such that the grating reflects back into the diode-laser a few percent (usually less than 10%) of radiation propagating in the core in a bandwidth less than about 1 nm about a peak-reflection wavelength determined by modulation period. This forces the diode laser to emit at the peak-reflection wavelength of the grating and with a bandwidth about equal to the reflection bandwidth of the grating.

This method however is not suitable for use with multimode fibers since a multimode fiber supports all the directions (angles) of propagation within its numerical aperture. The peak reflection wavelength of a fiber Bragg grating depends not only on the modulation period but on the angle of incidence of light on the grating. Accordingly, in a multimode fiber core, a Bragg grating would have a reflection bandwidth broadened by the plurality of angles at which the multimode light was incident thereon. The grating would provide neither adequate bandwidth narrowing nor adequate wavelength stabilization. There is a need for an arrangement for stabilizing the wavelength and narrowing the bandwidth of the output of a multimode fiber coupled, multimode diode-laser bar.

SUMMARY OF THE INVENTION

In one aspect, the present invention comprises a diode-laser emitter emitting an output beam along a propagation axis. The diode-laser has a fast axis and a slow axis perpendicular to each other and perpendicular to the propagation axis. The emitted beam diverges in the fast axis and in the slow axis, with the slow axis divergence being greater than the fast axis divergence. A lens is disposed on the propagation axis of the diode-laser. The lens is configured and aligned with the diode-laser such that the output beam is transmitted by said lens collimated in the fast axis and the slow axis divergence unchanged. A length of optical fiber is arranged to receive the transmitted output beam. The optical fiber has a core surrounded by a first cladding, the first cladding being surrounded by a second cladding. The first cladding has a lower refractive index than that of the core, and the second cladding has a lower refractive index than that of the first cladding. The core of the optical fiber includes a wavelength selective Bragg grating and has an elongated cross-section. The width of the cross-section is selected such that the core functions as a low-mode core in the width direction of the cross section. The length direction of the core is aligned with the fast axis of the diode-laser.

The fast axis collimated beam, together with cross-section shape of the core and the arrangement thereof with respect to the fast axis of the diode-laser, provides that the Bragg grating will only reflect the light that propagates along or parallel to the axis of the fiber. Tilted rays in the slow axis will not have sufficient path length in the core to interact effectively with the grating. This provides that the grating reflects in a bandwidth only about 1 nm or less back into the diode-laser thereby providing the desired spectral narrowing and wavelength stabilization of the diode-laser. Multimode light will propagate in the first cladding but having the stabilized wavelength and narrow bandwidth characteristics forced by the back reflection from the grating.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of the specification, schematically illustrate a preferred embodiment of the present invention, and together with the general description given above and the detailed description of the preferred embodiment given below, serve to explain the principles of the present invention.

FIGS. 1A and 1B are plan and elevation views schematically illustrating one embodiment of diode-laser apparatus in accordance with the present invention including a diode-laser bar having a plurality of emitters and a cylindrical lens arranged to couple output of the emitters into a corresponding plurality of double-clad optic fibers each thereof including a core having an elongated cross-section shape and having a Bragg grating written therein, the cross section shape being configured and arranged such that the core functions as a multimode core in the fast axis of the emitters and a low-mode core in the slow axis of the emitters.

FIG. 2 is end elevation view schematically illustrating detail of one preferred example of a double-clad optical fiber in the apparatus of FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawings wherein like features are designated by like reference numerals, FIG. 1A and FIG. 1B schematically illustrate a preferred embodiment 10 of a fiber-coupled diode-laser bar apparatus in accordance with the present invention. Apparatus 10 includes a diode-laser bar 12 including a plurality of spaced-apart individual emitters (diode-lasers) 14 arranged in a linear array. The diode-laser bar is mounted on a heat-sink 16.

Each emitter 14 in diode-laser bar 12 has a fast axis and a slow axis (Y-axis and X-axis respectively as depicted in FIGS. 1A-B). The individual emitters are aligned in the slow axis. Each emitter emits a beam of light 18 generally along a propagation axis 20 (the Z-axis as depicted in FIGS. 1A-B). Beam 18 diverges in the slow axis and the fast axis with the fast axis divergence being greater as discussed above. In FIG. 1A beam 18 is depicted by extreme slow-axis diverging rays 18S. In FIG. 1B beam 18 is depicted by extreme fast-axis diverging rays 18F.

A cylindrical microlens (lens) 22 is disposed on propagation axis 20 of the diode-lasers to receive and transmit the emitted beams. The lens is arranged to at least reduce the divergence of the fast axis rays on transmission and preferably to collimate the fast axis rays on transmission as depicted in FIG. 1B. The divergence of slow axis rays 18S is unchanged on transmission through lens 22.

Continuing with reference to FIGS. 1A and 1B and with reference in addition to FIG. 2, a plurality of double-clad optical fibers 24, equal in number to the number of emitter 14 in diode-laser bar 12, is arranged such that each one of the plurality of fibers a beam 18 from a corresponding one of the diode-lasers after the beam has been transmitted, and fast-axis collimated, by lens 18. Each fiber 24 has a core 26 having an elongated, here elliptical, cross-section (see FIG. 2). The core is “low-mode” in the width direction of core cross-section, that is to say the width (here the minor axis) W of the core is sufficiently narrow so only about 4 or less modes would be supported were the core circular (with a diameter W). A single-mode core, of course, would be a limiting case of a low-mode core. Core 26 is “multimode” in the length direction of the core cross-section, that is to say, the length (here the major axis) L of the core is sufficiently long that tens or even a hundred or more modes could be supported were the core circular (with a diameter L). By way of example, for light having a wavelength of about 808 nm, W is preferably about 30.0 micrometers (μm) or less and L is preferably about 50.0 μm or greater or greater. Core 26 has a Bragg grating 32 written into the core. The refractive index modulation depth of the grating is preferably selected such that the grating has a reflection bandwidth less than the gain bandwidth of the diode-laser and preferably less than about 1 nm. The grating period is selected such that the grating has a peak reflectivity at a wavelength within the gain-bandwidth of the diode-laser at which the output of the diode-laser is to be stabilized. The length of the grating is selected, consistent with the refractive index modulation, according to the reflectivity desired for the grating.

Core 26 is surrounded by a cladding 28 having a refractive index lower than the refractive index of the core. Cladding 28 is surrounded by a further cladding 30 having a refractive index lower than the refractive index of cladding 28. In one example of a fiber 24 for receiving 808 nm light core 26 has a length L of about 100.0 μm, and a width W of about 30.0 μm. Cladding 28 has a diameter of about 150.0 μm and cladding 30 has a diameter of about 165.0 μm. Note that the cladding 28 acts as a core for light whose divergence is too large to be accepted into the smaller core 26.

Each fiber 24 is arranged such that the length direction of the cross-section of core 26 thereof is aligned with the fast axis of the corresponding emitter 14. Any fast axis rays entering the core, having been collimated by lens 22, travel along or parallel to the longitudinal axis of the fiber. As core 26 has only a relatively narrow width compared to the beam width in the slow axis of an emitter, only those slow-axis rays propagating along or close to the fiber axis will enter core 26. Those slow axis rays that are not propagating exactly along the fiber axis will have too short an interaction with the grating to have any significant bandwidth broadening effect on back reflection from the grating. The configuration and arrangement of fiber 24 provides that essentially all rays interacting with grating 32 of core 26 interact with the grating at the same angle, i.e., paraxial to the longitudinal axis of the fiber, at about normal incidence to the grating. Note that this is true in the fast axis direction, even thought the core is longer since the rays in fast axis have been collimated by the lends. This approach the bandwidth broadening of a grating reflection band that would occur if the grating were written into a conventional multimode fiber core.

It is emphasized, here, that all rays in beam 18 that are within the numerical aperture (NA) of fiber 24 defined by the refractive index difference of inner cladding 28 and inner cladding 30 propagate in the cladding 28. Preferably the NA of fiber as so defined is about 0.15 or greater, for accepting the slow axis ray divergence. Fast axis rays, of course, are collimated. Most of the rays entering the fiber will propagate in inner cladding 28 thereof, while a small percentage, for example between about 10% and 20%, having characteristics discussed above will propagate in the core 26 and interact with grating 32. The NA of a fiber 24 as defined by the refractive index difference between core 26 and cladding 28 can be as low as about 0.07 or less, as the core is intended to carry paraxial rays in the fiber as discussed above.

It will be evident from the description provided above that inner cladding 28 can be considered the “multimode core” of fiber 24 as far as multimode beam transport aspects of the fiber are concerned. Core 26 serves only to carry the grating 32 and carry a small percentage of rays entering the fiber for providing back reflection into an emitter. Accordingly, a fiber 24 need be no longer than is necessary to provide a sufficient length of grating 32 to provide a desired reflectivity of the grating. By way of example a length of about 5.0 cm may be sufficient. This short length of fiber may then be spliced to a conventional multimode fiber for further transport of the emitter output. An example of this is depicted in FIGS. 1A and 1B wherein one fiber 24 is depicted as having a multimode fiber 34 spliced thereto. Fiber 34 has a multimode core 36 having about the same diameter as inner cladding 28 of fiber 24. Fiber 34 has a cladding 38 having about the same thickness as outer cladding 30 of fiber 24.

It may be possible to configure the core 26 as a conventional circular single mode core having a grating written therein. However, it is believed that the single mode core would intercept such a small fraction of the total beam that insufficient feedback would be provided even if the grating therein had a reflectivity of 100%. By elongating the core cross-section in the fast-axis direction, a sufficient proportion of the beam can be intercepted to provide adequate feedback with a grating having less than 100% reflectivity.

Regarding the reflectivity of grating 32, this should be significantly higher than would be the case in prior-art grating feedback practice as even with the elongated core 26 only a small percentage of the beam interacts with the grating as discussed above. Preferably, the grating has a reflectivity of about 50% percent or greater. This preference assumes that facet reflectivity of the emitters is between about 1% and 10% percent. Optimization of the grating reflectivity and reflection of output facets of the emitters for any particular case can be simply done by experiment. Many diode-laser bar chips can be fabricated in a single growth cycle. These can be provided with a range of output facet coatings for providing a range of facet reflectivities. Fibers 24 having gratings 32 of different reflectivity can be prepared and various combinations of diode-laser and fiber can be evaluated.

The present invention is described above as a preferred embodiment. The invention, however, is not limited to the embodiment described and depicted. Rather, the invention is limited only to the claims appended hereto. 

1. Optical apparatus comprising: a diode-laser emitter arranged to emit an output beam along a propagation axis, said diode-laser having fast axis, and a slow axis perpendicular to each other and perpendicular to said propagation axis, said beam having a first divergence in said fast axis and a second divergence in said slow axis, said second divergence being less than said first divergence, and said diode-laser having a gain-bandwidth; a lens disposed on said propagation axis of said diode-laser, said lens configured and aligned with said diode-laser such that said output beam is transmitted by said lens collimated in said fast axis and with said slow axis divergence unchanged; a length of optical fiber arranged to receive said transmitted output beam, said optical fiber having a core surrounded by a first cladding, said first cladding being surrounded by a second cladding, said first cladding having a lower refractive than that of said core, and said second cladding having a lower refractive index than that of said first cladding; said core including a wavelength-selective Bragg grating and having an elongated cross-section, said cross-section having a width selected such that said core functions as a low-mode core in said width direction of said cross section; and wherein said length direction of said core is aligned with said fast axis of said diode-laser.
 2. The apparatus of claim 1, wherein said diode-laser has a gain-bandwidth and said Bragg Grating has a reflection bandwidth less than said gain bandwidth and has a peak reflectivity within said gain-bandwidth.
 3. The apparatus of claim 2, wherein said Bragg grating has a reflectivity greater than about 50%.
 4. The apparatus of claim 1, wherein said core has an elliptical cross-section, said length and width thereof corresponding respectively to major and minor axes of said elliptical cross-section.
 5. The apparatus of claim 4, wherein said width of said core is about 30 microns or less, and said length of said core is about 50 microns or greater.
 6. The apparatus of claim 1, wherein said optical fiber has a first numerical aperture defined by the refractive indices of said first and second cladding, and said numerical aperture is about 0.15 or greater.
 7. The apparatus of claim 1, wherein said optical fiber has a second numerical aperture defined by the refractive indices of said core and said first cladding and said second numerical aperture is about 0.07 or less.
 8. Optical apparatus comprising: a diode-laser emitter having a gain bandwidth and arranged to emit an output beam along a propagation axis, said diode-laser having fast axis, and a slow axis perpendicular to each other and perpendicular to said propagation axis, and said beam having a first divergence in said fast axis and a second divergence in said slow axis, said second divergence being less than said first divergence; a lens disposed on said propagation axis of said diode-laser, said lens configured and aligned with said diode-laser such that said output beam is transmitted by said lens collimated in said fast axis and with said slow axis divergence unchanged; a first optical fiber arranged to receive said transmitted output beam, said optical fiber having a core surrounded by a first cladding, said first cladding being surrounded by a second cladding, said first cladding having a lower refractive than that of said core, and said second cladding having a lower refractive index than that of said first cladding; said core including a wavelength-selective Bragg grating having a reflection bandwidth less than the gain bandwidth of said diode-laser and a peak reflection at a wavelength within said gain-bandwidth; said core having an elongated cross-section, said cross-section having a width selected such that said core functions as a low-mode core in said width direction of said cross section, and said length direction of said core being aligned with said fast axis of said diode-laser; and wherein said diode-laser, said lens, and said optical fiber are so arranged that a first portion of said diode-laser output beam transmitted by said lens propagates in said first cladding of said optical fiber, a second portion of said diode-laser output beam transmitted by said lens is intercepted by said core, and a portion of said second portion of said beam is reflected by said Bragg grating, via said lens, back to said diode-laser.
 9. The apparatus of claim 8, wherein said second portion of said diode-laser output beam is between about 10% and 20%.
 10. The apparatus of claim 8, wherein said Bragg grating has a peak reflectivity of about 50% or greater.
 11. The apparatus of claim 8, further including a second optical fiber spliced to an exit face of said first optical fiber, said second optical fiber having a multimode core surrounded by a second cladding.
 12. The apparatus of claim 11, wherein said multimode core of said second optical fiber has a diameter about equal to the diameter of the first cladding of said first optical fiber.
 13. The apparatus of claim 8, wherein said optical fiber has a first numerical aperture defined by the refractive indices of said first and second cladding, and said numerical aperture is about 0.15 or greater.
 14. The apparatus of claim 8, wherein said optical fiber has a second numerical aperture defined by the refractive indices of said core and said first cladding and said second numerical aperture is about 0.7 or less.
 15. Optical apparatus comprising: a diode-laser emitter having fast axis and a slow axis perpendicular thereto, with light in the fast axis diverging faster than in the slow axis; a cylindrical lens positioned to substantially collimate light emitted along the fast axis; an optical fiber positioned to receive light transmitted by said lens, said optical fiber having a core surrounded by a first cladding, said first cladding being surrounded by a second cladding, said first cladding having a lower refractive than that of said core, and said second cladding having a lower refractive index than that of said first cladding, said core including a wavelength-selective Bragg grating; and with the later dimension of the core that is aligned with the slow axis being selected to substantially limit the cone of light accepted to propagate therethrough of those rays traveling in the slow axis so that the bandwidth of the light reflected from the Bragg grating back to the diode-laser emitter is substantially reduced.
 16. An optical apparatus as recited in claim 15, wherein the diameter of the core is configured so that only about 20% or less of the light in the slow axis propagates in the core.
 17. An optical apparatus as recited in claim 16, wherein the diameter of the core aligned with the fast axis is greater than the diameter of the core aligned with the slow axis direction. 